RU2196276C2 - Ventilation system with additional air admission to enhance draft - Google Patents

Abstract

FIELD: ventilation systems. SUBSTANCE: natural ventilation units for at least one apartment of house has air feed system supplying mentioned apartment with air and air exhaust system evacuating air from mentioned apartment. Air exhaust system has main riser whose outlet end is brought out to exhaust zone and inlet end is closed, and at least one outlet branch pipe brought out to mentioned apartment. Air feed system has main duct whose outlet end is closed and inlet one is brought out to first air source, at least one branch pipe for supplying air to at least one first additional air feeder designed to enhance draft. EFFECT: simplified design, enhanced ventilation effectiveness. 59 cl, 6 dwg

Description

 The invention relates to the field of ventilation and can be used for ventilation of at least one building premises.

 A known air supply system in at least one building room containing a main air supply channel with a pipe for air supply (RU 1691669 A1, 11/15/1991).

 A disadvantage of the known air supply system is the low efficiency of the system when changing the direction of the wind pressure.

 A known installation for natural ventilation of at least one room of a building, containing a system for supplying air to the room and a system for removing air from the room (RU 1691669 A1, 11/15/1991).

 A disadvantage of the known installation for natural ventilation of the building is the low efficiency when changing the direction of the wind pressure.

 The technical result of the invention is the possibility of natural ventilation in a simple, effective and inexpensive way.

 The technical result is achieved by the fact that the system contains a main channel, which extends essentially vertically and whose output end is closed, and the inlet is output to the first air source.

 The main channel contains at least one pipe for supplying air, installed in the hole made in the main channel between the inlet and outlet ends, and brought into the corresponding room.

 The system also contains at least one first device for introducing additional air for two types of draft located at the inlet end of the main channel.

 The device for introducing additional air is intended for the suction of air coming from the first air source, in the direction of the output end of the main channel.

 The specified suction is enhanced by the introduction of additional air.

 Thus, the flow rate of air introduced into one or more rooms increases.

 Such a system may also include means for filtering and / or treating the air leaving the first air source located at the inlet end of the main channel.

 It is also possible to filter, process, heat or cool additional air introduced by the first device for introducing additional air.

 The present invention provides various embodiments of a first device for introducing additional air.

So, for example, in accordance with the first embodiment of the invention, the first device for introducing additional air contains:
- an additional channel, the first end of which is located at the input end of the main channel and output to it, and the second end is output to the second air source,
- means for introducing additional air installed in the main channel at the level of connection of the latter with the first end of the additional channel;
wherein additionally introduced air leaving the second air source and passing through the additional channel is introduced into the main channel in the same direction as the air from the first air source.

 It is advisable that the first and second air sources were performed separately.

According to one embodiment of the invention, the means for introducing additional air comprise:
- at least one inlet nozzle or similar element located in the main channel and fixed in it, and
- at least one inlet channel connecting the nozzle or nozzles with an additional channel.

 This embodiment of the device for introducing additional air may also include means for selectively controlling the operation of various nozzles and, optionally, at least one wall in the form of a venturi located behind the exit of the inlet nozzles.

According to a second embodiment of the invention, the first device for introducing additional air comprises:
- an additional channel constituting part of the main channel, and
- a part covered by the main channel and located in front of the entrance to the extreme part of the additional channel coaxially with it.

 The specified part is made in the form of a sleeve forming an inner passage for additional air and containing hollow grooves extending along its outer surface from the free inner end edge to the peripheral zone.

 Hollow grooves together with an additional channel serve to limit the channels for introducing additional air.

 In addition, the peripheral zone together with the additional channel serve to limit the space for collecting additional air.

 More specifically, the specified part contains the first part in the form of a crown, limiting the grooves and including the peripheral zone, and the second part forming a support, and the first part is mounted on the second part.

 The additional channel contains a first section located opposite the outer surface of the specified part containing the grooves, and close to this surface with the formation of channels for introducing additional air, and a second section located opposite the peripheral zone and spaced from it with the formation between the corresponding outer surface of the specified part and the second section of the annular space forming a collection chamber for additional air.

 In the second section, at least one hole for introducing air is discharged into said chamber.

 The air supply means communicate with the collection chamber through this opening.

 The second part of this part is inserted into the main channel after the second section, which is part of the main channel.

 It is also possible the presence of an intermediate part, covering the first device for introducing additional air at least opposite the grooves.

 The invention also relates to an installation for natural ventilation of at least one room of a building, containing the proposed system for supplying air to the specified room and a system for removing air from this room.

The installation contains:
- the main riser, which runs essentially vertically and whose output end is brought out to the removal zone, and the input end is closed, and
- at least one outlet pipe installed in the hole made in the main riser between its inlet and outlet ends, and brought into the appropriate room.

 In addition, the installation comprises a second device for introducing additional air, essentially similar to the first device for introducing additional air of the air supply system and installed at the output end of the main riser.

 In addition, the air removal system may include a static or statomechanical exhaust device located at some distance from the output end of the main riser.

 The first air source of the air supply system can be separated from the removal zone into which the main riser is discharged.

 In the second case, the installation may additionally include a second riser, covering the main riser and brought out on the one hand to the removal zone, and, on the other hand, into the supply pipe connected to the main channel of the air supply system; and in the space separating the main riser from the second riser, air enters from the removal zone, which is then sucked into the supply pipe, and then into the main channel of the air supply system.

 The advantage of this installation is, in particular, the possibility of natural ventilation of the room in a simple, effective and inexpensive way.

 In addition, the second embodiment of the proposed installation, containing a second vertical riser, has the advantage that the air coming from the removal zone can naturally be heated during its movement between the second and main risers in the direction of the supply pipe due to contact with the main riser .

 The invention is better understood from the following detailed description with reference to the accompanying drawings, given by way of non-limiting example.

 Figure 1 depicts a schematic view of the proposed installation for natural ventilation of several rooms of the building, corresponding to the first embodiment of the invention.

 FIG. 2 and 3 schematically depict two versions of a device for introducing additional air.

 Figures 4 and 5 depict two options for means for introducing additional air, which can be used in the device for introducing additional air, shown in figure 2.

 Finally, FIG. 6 depicts a schematic view of the proposed installation for natural ventilation of at least one room of a building in accordance with a second embodiment of the invention.

 The invention relates to an air supply system, indicated by the number 1 position in figures 1 and 6, in at least one room 2 of building 3, for example a residential building.

 In this description, the term "air" refers to natural air or other gaseous working medium.

 1 and 6 schematically depict a part of a building 3 containing several rooms 2 located on different floors 2a, 2b.

 The air supply system 1 comprises a main channel 4 extending almost vertically through the building from floor 2a to another floor 2b and between two adjacent rooms 2 of floors 2a, 2b.

 Further in the description, the terms “input”, “input” means any extreme part of the element located on the side of the lower part 3a of building 3, that is, on the side of the building’s foundation, and by the terms “exit”, “output” - any extreme part of the element, located on the upper side 3b of the building 3, that is, from the side opposite the foundation.

 The output end 4a of channel 4 is thus located adjacent to the upper part 3b of building 3 and is closed.

 In this case, the inlet end 4b of the main channel is located in the lower part 3a of building 3 and is discharged into the first air source 5, for example, in a special room.

 Channel 4 in the shown embodiments of the invention has a substantially circular cross-section, with the exception of the channel shown in figure 4, where its cross section is essentially square.

 At least one pipe 6 for supplying air is installed in the hole made in the channel 4, essentially opposite each room 2.

 More specifically, in the embodiments of the invention shown in FIGS. 1 and 6, the nozzles 6 are made in the form of the corresponding free end of the channel 6a, which can be made in the form of a parallel branch or knee and one section of which extends generally parallel to the channel 4 approximately to a height premises 2.

 The portion of the channel 6a installed in the hole made in the channel 4, in turn, is essentially perpendicular to this channel.

 It can also be envisaged that the nozzles 6 are installed in an opening made either directly in the channel 4 or in a single channel extending essentially perpendicular to the channel 4.

 The air from the first source 5 by means of natural draft enters the channel 4 through its end 4b towards the output end 4a and is thus distributed to each room 2 through the nozzles 6.

 At least one first device 7 for introducing additional air is located at the inlet end 4b to increase the air leakage into the channel 4.

 More precisely, the device 7 is located behind the exit from the first source 5 and next to it.

 The flow of air entering the premises 2 is thus more active, while the intensity of the air inlet by the first source 5 has not increased.

 Various embodiments of device 7 may be provided.

 Only two embodiments are described below, although it is obvious that other variations of the device for introducing additional air are possible within the scope of the present invention.

 In accordance with the first embodiment of the present invention shown in FIG. 2, the device 7 comprises an additional channel 8, the first end of which 8a is located at the input end 4b of the channel 4 and is output to this channel, and its second end 8b is output to the second air source 9 .

 Channel 8 is installed in the hole made in the channel 4, in the area of the input end 4b of the latter.

 At least one inlet channel 10, leaving section 10a in channel 8, passes through its first end 8a to another section, namely, section 10b located in channel 4.

 From its free end 10b, the channel 10 is connected to at least one inlet nozzle 11 or to a similar element.

 Thus, in the channel 4 there is at least one nozzle 11, which can be fixed in it.

 Channel 10 or channels 10 and nozzle 11 or nozzle 11 together form means 12 for introducing additional air.

 With this embodiment of the invention, the channel 10 is located or the channels 10 are located essentially before the entrance to the nozzles 11, so as not to interfere with the air suction flow from these nozzles 11.

 According to the embodiment of FIG. 2, the channel 10 extends horizontally as a whole and contains only one nozzle 11.

 This nozzle 11 is located essentially on the axis D of the channel 4. Its free end, through which additional air is introduced, is directed towards the end 4a of the channel 4.

 According to the embodiment of FIG. 2, the first 5 and second 9 air sources are made separately.

 Nonetheless, an option is possible when these sources are made together.

 Air from the second source 9 moves inside the channel 8 from its second end 8b to the end 10a of the channel 10 in the direction of the arrow F2.

 Then it follows the channel 10 and exits through the nozzle 11.

 Various embodiments of means 12 may be provided.

 So, for example, as provided for in the embodiments of FIGS. 2 and 4, it is possible to have only one nozzle 11 located centrally along the D axis or essentially along the D axis of the main channel 4.

 It is advisable, in accordance with one embodiment of the invention, to provide a large number of nozzles 11 located in close proximity to the axis D.

 According to another embodiment of the invention, such as the embodiment of FIG. 5, several nozzles 11 are provided located at different places in the channel 4 on the D axis and / or at some distance from it.

 These several nozzles 11 are essentially either in one plane (not shown), transverse to the channel 4, or in several transverse planes, as shown in Fig.5.

In the latter case, these transverse planes are the input plane P ₁ and the output plane P ₂ .

At least one central nozzle or at least one peripheral nozzle are located in the plane P ₁ (FIG. 5). In the plane P ₂ , peripheral nozzles or at least one central nozzle are located (FIG. 5).

 In general, the variant with a large number of nozzles 11 comprises at least one central nozzle 11 'located on or near the axis D, and / or at least one peripheral nozzle 11 "located near the wall 4c of the channel 4, and / or several middle nozzles (not shown) located between the axis D and the wall 4c.

 The 11 "nozzles and the middle nozzles according to one embodiment of the present invention are uniformly distributed around the D axis, either at intervals or in a continuous row. For example, these nozzles can be arranged in the form of a crown.

 In any case, the various nozzles 11, 11 ', 11 "are so located relative to each other that they essentially do not interfere with the passage of air coming from the inlet of the channel 4. In fact, it is advisable that the air flow is not too disturbed due to the presence of introduction nozzles.

 According to another embodiment of the invention (not shown), the nozzles 11 are mounted in rows and columns and are supported by a perforated plate located in the channel 4 and fixed therein. This plate can be either flat or curved.

 In an embodiment with a large number of nozzles 11, the device 7 typically comprises means (not shown) for selectively controlling the operation of various nozzles. In fact, in this case it is not necessary that all nozzles work continuously and in the same way.

 According to a possible embodiment of the invention, the physical characteristics of the suction air flow generated by the various nozzles 11, such as the flow rate, velocity or divergence of the flow, are identical or close to each other.

 On the contrary, in accordance with another embodiment, these characteristics are differentiated by nozzles depending on the requirements for them. For example, the flow rate and speed in the central nozzle 11 'may be greater than in the peripheral nozzle 11 ".

 In addition, these physical characteristics can be constant in time, or adjustable, depending on the requirements for ensuring normal operation. To this end, the device 7 may include means for regulating these physical characteristics.

 So, for example, all nozzles or part of them are not involved, and air is not introduced if the traction is sufficient for normal ventilation. On the contrary, all nozzles are included in the work when natural traction is not enough for this.

 In addition, the distance between the different nozzles 11 and the output end 4a of the channel 4 is either the same or differentiated for the nozzles 11 depending on the conditions ensuring normal operation.

 This distance is either constant in time or adjustable.

 In the latter case, at least one nozzle is installed with the possibility of regulation by its smooth movement parallel to the axis D, as described below.

 Due to the fact that at least one channel 10 is located essentially in front of the nozzles 11, the space behind the nozzles is free.

 However, in accordance with another embodiment of the invention, shown in more detail in FIG. 2, it is possible to install at least one wall 13 in the form of a venturi installed behind the outlet of the nozzles 11 and connected to them.

 For example, there may be a wall in the form of a venturi adjacent to the wall 4c of channel 4 (not shown), and / or a wall in the form of a venturi for at least one inlet nozzle, in particular for one type of nozzle, for example, a central one (Fig. 2 ), peripheral or median.

 Similarly, in accordance with another embodiment of the invention (not shown), a diffuser (not shown) can be installed in the channel 4 behind the nozzles 11, giving the air flow an appropriate laminar character.

 Nozzles 11 or similar devices may also have various embodiments.

 For example, the nozzle 11 may be configured to provide a stream in the form of a narrow beam, or a wide beam, or a spiral jet.

 The axis of the gaseous working medium flow coming from the nozzle 11 can either be constant or may be displaced. In the first case, this axis is either parallel to the axis D (Fig.2, 5 and 6), or inclined with respect to it. In the second case, the device 7 comprises means for moving the axis of the movable nozzles and means (not shown) for controlling these means.

 In accordance with another embodiment of the invention, the device 7 also comprises means for changing the flow rate and / or velocity of the suction air flow depending on the requirements. These means of changing the flow include, in particular, means for automatically controlling the input of the gaseous working medium for suctioning the main stream, for example, a clock, a temperature sensor, a pressure switch or a hydrostatic sensor.

 In accordance with one feature of the invention, the nozzle 11 is located or the nozzles 11 are generally stationary in the channel 4, at least from the point of view of the distance to the axis D.

 In accordance with another embodiment of the invention (not shown), at least one nozzle is mounted with the possibility of adjustment by smoothly moving it parallel to the axis D between two extreme positions, respectively closest and more distant.

 According to this embodiment of the invention, the device 7 comprises means for guiding the movement of at least one nozzle 11 configured to move. The device 7 also contains a device for driving nozzles and controls this device.

 For example, nozzles may be installed in portions of channels assembled to move one another. Or, the nozzles can be installed on the system in the form of a deformable parallelogram, while remaining connected to the channel 10 by means of flexible pipelines.

 These embodiments of the invention do not exclude the use of other designs.

 In accordance with the embodiment of the invention illustrated in FIG. 4, the device 7 comprises a single nozzle 11 extending along the D axis of the channel 4 with a square cross section.

 The nozzle 11 is fixed in the channel 4 by means of elastic parts 14a and 14b rigidly fixed to the walls 4c of the main channel 4.

 More specifically, the parts 14a and 14b are respectively made in the form of a rod, for example, metal, partly in the region of its middle covering the nozzle body 11.

 Each rod 14a, 14b mounted on the nozzle 11 has a length approximately equal to the distance separating the two opposite walls 4c of the main channel, or the diameter of the channel 4, in the case when it has a circular cross section.

 The rods 14a and 14b may be in two extreme positions, namely, in the first extreme position in which their ends 15 do not contact the walls 4c, and the nozzle 11 can thus move freely, and in the second extreme position in which the ends 15 are in close contact with the wall 4c of the channel 4.

 In the embodiment of the invention shown in FIG. 4, the portion 10a of the channel 10 extends substantially perpendicularly to the general direction of the nozzle 11 and therefore the D axis along the diagonal D ′ of the transverse square section of the channel 4.

 The portion 10a from the side opposite the nozzle 11 is connected on one side to the second portion 10b extending to the channel 8, as indicated above, and on the other hand, to the tube 16, which runs essentially parallel to the axis D.

 The tube 16 is hollow and connected to a handle 17 located outside the channel 4.

 A cable is located in the tube 16 and along its walls, connected on one side to the handle 17, and on the other to the end 15 of each rod 14a, 14b, respectively.

 The manipulation of the handle 17 allows you to stretch or loosen the cable 18.

 When the cable 18 is tensioned, both rods 14a and 14b are located next to each other in the first extreme position, i.e., essentially parallel to the first channel portion 10a.

 In this position, the nozzle 11 can be freely moved in the axial, radial or other direction.

 In addition, when the handle 17 is in the opposite fixed position, the cable 18 is weakened and allows the rods 14a and 14b to be moved apart from each other until they are placed in the second extreme position, in which the nozzle is locked.

 Thus, in order to move from the first extreme position to the second, the rods 14a and 14b perform relative movements to one another, similar to the movements of the two ends of the scissors.

 Fixing means ensure the fastening of the handle 17 in each extreme position.

 It is quite obvious that the described device for rigidly fixing the nozzle can be used with nozzles of other types than those shown in Fig. 4, and in the channel 4 of a different type with different cross sections, for example, with the described square section.

 It is also possible the presence of other types of channel 10 and tube 16 or their location.

 It is possible, for example, the presence in the tube 16 of several tubes mounted with the possibility of moving one into another, which makes it possible to control one or more nozzles 11 by moving them parallel to the axis D, as indicated above.

 In addition, in the embodiment with a large number of nozzles 11, there may be as many devices for rigid fixation as there are nozzles 11.

 As follows from figure 2, in the device 7 in the region of the second end 8b of the channel 8 after the second source 9 can be sequentially installed means 19 of the suction of additional air, for example a device with a drive (fan or the like), and / or means 20 of filtering and / or processing additional air, and / or means 21 for heating or cooling the additional air.

 The means 19, 20 and 21 are air exhaust devices commonly used in the prior art.

 Finally, in the first embodiment of the device 7, it is also possible to have means 22 for filtering and / or treating the air coming from the first source 5 of the same type as the means 20.

 Means 22 may be located, for example, in channel 4 in front of the first end 8a of channel 8, and therefore, in front of input means 12.

 However, there may be a variant in which the means 22 are located behind the means 12.

 Their purpose in this case is to filter the primary air mixed with additional air from a second source.

 The following is a description of a second embodiment of the first device 7 shown in FIG. 3.

 The device 7 includes an additional channel 23, which is part of the channel 4, and part 24, covered by the channel 4 and mounted coaxially in front of the extreme part 23a of the channel 23.

 Part 24 is made in the form of a hollow sleeve with a longitudinal axis L and forms an internal passage 24 'for air coming from the first source 5.

 In the illustrated embodiment, the sleeve 24 consists of two hollow parts 24a and 24b located adjacent and coaxial.

 The first part 24a is formed by the inner surface 25 and the outer surface 27 extending along the axis L.

 The surface 25 has a constant cross section, substantially circular. It also has a substantially cylindrical shape.

 The annular wall 26 of the sleeve has some variable thickness along the axis L.

 More specifically, surface 27 has a substantially truncated cone shape.

In the illustrated embodiment, the surface 27 is inclined relative to the surface 25 or with respect to the longitudinal axis L at an angle of 5 to 30 ^° , preferably at an angle of about 10 ^° .

 The surface 27 is thus limited on one side by an end free edge of a small section, indicated by 27a, and on the other side by a large section edge, indicated by 27b.

 The surface 27 in the direction of the L axis contains grooves 28 extending only from the edge 27a to the peripheral zone 27c, which, in turn, is limited by the edge 27b.

 The grooves 28 are in this case essentially axial direction. They can also be spiral or other forms.

It is also possible their execution inclined relative to the axis L at an angle of 40 ^o .

 Zone 27c is substantially smooth. Grooves 28 are also possible.

 Zone 27c extends from about one fourth to one eighth, preferably one sixth, of the height of the first part 24a along the L axis, starting from a large section edge 27b.

 The grooves 28 are evenly distributed on the outer surface of the sleeve 24 around its axis L, and there are enough of them to be placed substantially close to each other.

 The second part 24b of the part 24 is adjacent to the first part opposite to the small section edge 27a and is aligned with this part.

 More specifically, the portion 24b is adjacent to the region 27c along the edge 27b.

 In this case, the sleeve 24 is made integral.

 Nevertheless, it is possible that the first 24a and second 24b parts are separate and rigidly fixed to one another.

 The second part 24b as a continuation of the inner cylindrical surface 25 has an inner surface 30 of the same shape with a length of approximately one fourth to one eighth, preferably one sixth of its height from the edge 27b along the L axis, and the next surface is then essentially in the form of a truncated cone.

 The large base 30b of the truncated cone inner surface 30 is farthest from the cylindrical surface 25 along the L axis.

 It is also possible to make the surface 30 of the second part 24b in the form of a truncated cone, starting from the edge 27b. Moreover, the small base 30a of the inner surface 30 corresponds to the edge of the inner cylindrical surface 25.

In accordance with the depicted embodiment, the surface 30 of the second part 24b is inclined relative to the inner cylindrical surface 25, and therefore, the axis L in the range from about 10 to 40 ^o , in particular about 25 ^o .

 The outer surface 31 of the second part 24b has a substantially circular cross section, the diameter of which is larger than the diameter of the outer surface 27 of the first part 24a. More specifically, surface 31 has a substantially cylindrical shape.

 As can be seen in the drawing, the surface 31 has a radial ledge 32 relative to the outer surface 27.

 The ledge 32 thus forms a boundary between the first 24a and second 24b parts.

 The ledge 32 comprises a fixture 32a for fixing such an element as, for example, an additional channel.

 The device 32a is made in the form of at least one hole, for example, a threaded hole in the body of the second part 24b, which extends substantially parallel to the axis L from the radial ledge 32. This hole is made so that a part of the corresponding shape, for example a screw, is installed in it.

 Holes 32b of a similar type extend substantially perpendicular to the axis L and are designed to fit, for example, a screw to secure an additional part to the extreme lower part of the second part 24b.

 Part 24 is made, for example, of metal.

 At least the first part 24a of the part 24, containing the grooves 28, is rigidly fixed inside the outer part 23a of the additional channel.

 This fastening is made rigid, but detachable, for example by means of bolts, or fastening rings, or in a similar way.

 In addition, the assembly is made in such a way that the part 24 extends coaxially to the channel 23.

 Channel 23 contains at least two sections 33, 35, the walls of which, both internal and external, are made essentially smooth and rectilinear.

 The first section 33 is located opposite the outer surface 27 of the part 24 containing the grooves 28, and close to this surface with the formation of channels for introducing additional air between two adjacent grooves.

 The second section 35, adjacent to the first 33, is located opposite the peripheral zone 27c and is separated from it with the formation of an annular space between them, forming on the periphery of the collection chamber 36 for additional air.

 In this case, the portion 35 forms an extreme portion of the channel portion 23a.

 Channel 23 has a substantially annular cross section.

 The first section 33 of the channel 23 is made in the form of a truncated cone, the small base of which is located essentially opposite the free edge 27a of the part 24, and its large base is located essentially opposite the boundary between the grooves 28 and the zone 27c.

 In addition, the portion 35 of the channel 23 is substantially cylindrical, with the radial collar 33a externally forming a joint between the first 33 and the second 35 portions.

 Therefore, the cross section of section 35 is larger than the section of section 33.

 In addition, the space separating the portion 35 from the first part 24a is larger than the space separating the portion 33 from the same part 24a.

 The size of the space located between the first section 33, respectively, the second section 35 and the part 24, can be adjusted by installing gaskets (not shown) between the ledge 32 and the free end 35a of the channel 23.

 The chamber 36 communicates with air supply means 37, such as at least one tube, connected to the portion 35 through at least one opening discharged into this chamber 36.

 In the embodiment of the invention shown in the drawing, the means 37 are located essentially at the level of the ledge 32.

 Means 37 are associated with a second air source 9, made in this case separately from the first source 5.

 Similarly to the embodiment of the device 7 shown in FIG. 2, there may be between the second source 9 and the air supply opening means for suctioning additional air and / or means 20 for filtering and / or treating this air and / or means 21 for heating or cooling air.

 The continuation of the channel 23 from the first part from the side opposite the section 35 is a free section 34.

 This portion 34 is essentially a truncated cone shape, a small section 34a of which is adjacent to the section 33, and a large section 34b is located on the side opposite to the part 24.

 Section 34a is thus similar to and coincides with the small section of section 33.

 This shape in the form of an hourglass allows you to give the design the effect of a venturi.

 In this case, the plot 34 is made in one piece with the channel 23.

 At least part of the second part 24b of the part 24 is rigidly fixed in the second additional channel 38 connected to the channel 4 and coaxial with it.

 If necessary, means 22 for filtering and / or treating the air coming from the first source 5 are installed between the second channel 38 and channel 4.

 To ensure the tightness of the device 7 provides for the installation of an intermediate part 39.

 Part 39 covers the first part 24a of part 24 containing the grooves 28, and at least a portion 33 of the channel 23.

 More specifically, in accordance with the embodiment of the invention shown in FIG. 3, part 39 spans along the L axis at least a portion of portion 34, portion 33, portion 35, at least one portion of the second portion 24b of part 24, and extends substantially to focus in the second section 38.

 Part 39 extends coaxially with channel 23 and part 24 and is rigidly fixed coaxially with channel 4.

 Thus, in accordance with the shown embodiment of the invention, the part 39 contains two adjacent parts of a substantially cylindrical shape. One of these smaller sections 39a spans the channel 23, while the other 39b spans the second portion 24b of the part 24.

 The connection of these two parts 39a and 39b is at the level of the ledge 32.

 In this embodiment, the additional air coming from the second source 9 is supplied through the inlet channel 37 to the chamber 36.

 Then, additional air is directed into the channel 4 through the channels formed by the grooves 28 and located between the first part of the section 33 and the first part 24a of the part 24.

 Thus, additional air enters the channel 4 along the walls of section 34 in the direction of the arrows F '.

 The additional air is thus introduced at the periphery, and not at the center, and draws in a gaseous fluid removed by natural draft.

 It should be noted that additional gaseous fluid can be introduced through the grooves at a speed of approximately from 20 to 160 m / s, which significantly increases the rate of suction of primary air.

 The invention also relates to an installation for natural ventilation of at least one room 2 of a building 3.

 This installation, two embodiments of which are shown in FIGS. 1 and 6, includes an air supply system 1 of the type described above, configured to introduce air into at least one room 2, as indicated above, and an air removal system 40 from this room 2 .

 Thus, as is clearly seen in FIGS. 1 and 6, air is introduced into each room 2 through the system 1 and discharged through the system 40.

 In accordance with the embodiments of FIG. 1 and 6, the system 40 includes a main riser 41 extending substantially vertically separately from the main channel 4 of the system 1.

 More precisely, on both sides of each room 2, channel 4 is installed on one side and a riser 41 on the other.

 In these embodiments of the invention, the riser 41 has a substantially circular cross section.

 Obviously, other cross-sectional shapes of this riser are possible, for example, square.

 The output end 41a of the main riser is brought into the removal zone 42.

 Zone 42 is located outside of building 3.

 In addition, the inlet end 41b of the main riser located in the lower part 3b of the building 3 is closed.

 At least one exhaust pipe 43 for removing air is installed in the hole made in the riser 41 between its inlet 41b and outlet 41a ends.

 Each pipe 43 is displayed in the corresponding room 2.

 The nozzles 43 are similar to the nozzles 6 described above with reference to the system 1.

 The air coming from rooms 2 is thus sucked into zone 42 in the direction indicated by arrows F2.

 A second device 44 for introducing additional air is installed at the output end 41A of the riser 41.

 In a preferred embodiment of the invention, a second device for introducing additional air is located outside the building 3. It thus provides for an increase in the suction of air to zone 42.

 The device 44 is essentially similar to the device 7, two embodiments of which are described above with reference to FIGS. 2 and 3.

 The system 40 further comprises a static or statomechanical exhaust device 45 located behind the device 44 at a distance from the output end 41 a of the riser 41.

 Obviously, the second device 44 and / or the exhaust device 45 may not be included in the system 40.

 Static, for example 45, or statomechanical, or dynamic exhaust devices can have various embodiments.

 In particular, static exhaust devices can be made in accordance with the following patent documents: FR-A-2658271, FR-A-2709533, FR-A-2709534, FR-A-2374591, FR-A-2438795 and FR-A- 2518710.

 Below, with reference to FIGS. 1 and 6, the static exhaust device 19 is described in more detail, it being obvious that the statomechanical or dynamic exhaust device may have a similar shape.

 The static exhaust device 45 comprises a lower part 46 and an upper part 47 coaxial with the axis 48. The shape of the lower 46 and upper 47 parts is obtained by rotating the generatrix around this axis, and these parts have the same or approximately the same diameter.

 Both parts, the upper 47 and the lower 46, are spaced one relative to the other with the formation between them of a free space 49, which in axial section has the shape of a Venturi tube as a whole.

 For this, the lower 46 and upper 47 parts are rigidly connected to each other along the axis 48 by means of mutual connecting spacers 50.

 Since the spacers 50 are in the form of flat profiles, they are made in the form of radial planes to avoid excessive windage.

 The corresponding walls of the lower 46 and upper 47 parts are solid, that is, there are no holes in them, with the exception of the passage 51 made in the lower part 46. This passage 51, which serves to pass the exhaust air or air to create a suction, is communicated in its lower if necessary parts with riser 41 and displayed in the upper part, into space 49.

 If necessary, the riser 41 can form a diffuser in the lower part 46. Moreover, a crossbar can be installed in the outlet of the passage 51.

 In the presented embodiment, the axis 48 coincides with the axis L of the riser 41. In other embodiments, not shown, the axis 48 may be slightly inclined relative to the axis L and relative to the vertical.

 In the present embodiment, the lower portion 46 comprises an upper wall 52 and a lower wall 53.

 Both the upper 52 and lower 53 walls have the same shape of a truncated cone. The small base 54 of the wall 52 faces the upper part 47 of the space 49. The large base 55 of the wall 52 faces the riser 41 and is common with the large base of the lower wall 53, the small base of which faces the riser 41.

 Similarly, the upper part 47 comprises a lower wall 56 and an upper wall 57.

 The bottom wall 56 in the shown embodiment has a generally conical shape. In another possible embodiment, the bottom wall 56 has a generally truncated cone shape.

 In both one and the second possible embodiments of the invention, the top 58 or the small base of the wall 56 faces the lower part 46, that is, the space 49. The large base 59, in turn, is located opposite the riser 41.

 In the present embodiment, the upper wall 57 is generally conical in shape. In accordance with another embodiment, the upper wall 57 has a generally truncated cone or hemisphere shape, or a complex shape derived from previous shapes. The upper wall 57 has a common large base with a large base 59 and thus faces the bottom 46.

 The spacers 50 are connected, for example, with the wall 52 of part 46 and with the wall 56 of part 47.

 Although in this case the drawings show a static type device 45, it is also assumed within the scope of the present invention that said exhaust device may be of a statomechanical type. In this case (not shown), the device 45 also includes an integrated turbine.

 Such exhaust devices are particularly described in patent documents FR-A-2651563, FR-A-2374591, FR-A-2514469 and FR-A-2709534.

 The turbine contains blades located in the space 49 or in the space formed in the upper part 47.

 In accordance with the second embodiment of the proposed installation, shown in Fig.6, the second riser 59 covers the main riser 41.

 The riser 59 is brought out on the one hand to the removal zone 42, and therefore outward relative to the building 3, and on the other hand, to the supply pipe 60, which is connected to the channel 4 of the system 1.

 In a first embodiment, the riser 59 has a substantially circular cross section with a diameter greater than the diameter of the riser 41.

 Obviously, other embodiments of the invention are not excluded.

 In addition, the riser 59, as well as the riser 41 and the channel 4 can be solid or consist of a number of sections forming a line, coaxial or fixed in pairs.

 The space 61 separating the riser 59 from the riser 41 is large enough for the passage of air from zone 42 in the direction shown by arrows F3.

 This air, therefore, due to natural draft is directed to the lower part 3a of the building 3, that is, to the output end 59b of the riser 59.

 Then this air is directed through the supply pipe 60 into the channel 4 of the system 1.

 Under these conditions, the first source 5 is combined with zone 42.

 The advantage of this installation is that it provides natural heating of the air circulating in the second riser 59, due to the contact of this air with the outer walls of the riser 41.

 Holes 62 are made in the wall of the riser 59 to accommodate at least one pipe 43 mounted in an opening made in the riser 41.

 In this embodiment, it is also possible for the pipe 60 to have a bypass system 63 connected to a fresh air source 64.

 Thus, for example, in the case where the air supplied to the channel 4 should not be too warm (for example, in summer), the system 63 ensures that the input end 59b of the riser 59 is closed and the output end of the source 64 is opened.

 Of course, the invention is not limited to the embodiments described above.

 In this regard, it is also possible to use a static, statomechanical or dynamic exhaust device, which is similar to the device 45 described above, but in which the lower 46 and upper parts 47 do not have the general shape of the surface of rotation around axis 48, as in device 45, but have an elongated shape in the direction perpendicular to axis 48.

 In this case, the lower 27, 30 and upper 26, 31 walls have a common prismatic shape.

 So, for example, the small base 54 of the upper wall 52 and, if necessary, the small base of the lower wall 56 may have a rectangular rather than square cross section, as is the case in the device 45.

 In addition, in the case when the device 44 is located outside the building 3, towering above its roof, it is possible to mount it with a screed to ensure the tightness of this mount.

 In addition, the base covering the riser 41 only from the screed to the device 45 can be rigidly fixed to this screed.

 This base is made, for example, of a metal billet.

 In accordance with another embodiment, the base walls are spaced a sufficient distance from the extreme outlet of the riser 41 and the device 44 with the formation of free space between them for isolation, for example, from external cold or warm air currents. Such insulation is, for example, made of mineral wool or similar material fixed to the inner walls of the base.

Claims (59)

 1. An air supply system in at least one room (2) of a building (3), characterized in that it comprises: a main channel (4) that extends substantially vertically and whose output end (4a) is closed and the input end ( 4b) is led out to a first air source (5), and which contains at least one pipe (6) for supplying air, installed in an opening formed in the main channel between the inlet and outlet ends, and discharged into the corresponding room (2), and at least one first device (7) for introducing additional air for odeystviya rod disposed at the inlet end (4b) of the main channel and serves for sucking air from the first air source (5) to the outlet end (4a) of the main channel.  2. The system according to claim 1, characterized in that it further comprises means (22) for filtering and / or treating the introduced air located at the inlet end (4b) of the main channel.  3. The system according to p. 1 or 2, characterized in that the first device for introducing additional air contains: an additional channel (8), the first end (8a) of which is located at the input end (4b) of the main channel and is led out into it, and the second the end (8b) is discharged into the second air source (9), and the additional air input means (12) installed in the main channel (4) at the level of connection of the last (4) with the first end (8a) of the additional channel, with additional air, emerging from the second air source (9) and moving along an additional channel (8), is introduced into the main channel (4) in the same direction (F1) of movement as the air coming from the first air source (5).  4. The system according to p. 3, characterized in that the first (5) and second (9) air sources are made separately.  5. A system according to claim 3 or 4, characterized in that the means (12) for introducing additional air comprise: at least one inlet nozzle (11) or a similar element located in the main channel (4) and fixed therein, and at least one inlet channel (10) connecting the nozzle or nozzles with an additional channel (8).  6. The system according to claim 5, characterized in that the inlet channel (10) is located or the inlet channels (10) are located essentially in front of the inlet nozzle (11).  7. The system according to claim 5 or 6, characterized in that the inlet nozzle (11) is located or the inlet nozzles (10) are generally stationary in the main channel (4) at least from the point of view of the distance to the axis (D) of the main channel (4).  8. The system according to any one of paragraphs. 5-7, characterized in that the nozzle (11) is installed or the nozzle (11) is mounted in a fixed position in the main channel (4) by means of elastic parts (14a, 14b) rigidly fixed to its walls (4c).  9. The system according to any one of paragraphs. 5-8, characterized in that it contains one inlet nozzle (11) located on the axis (D) of the main channel or essentially on this axis, or several inlet nozzles located in close proximity to the same axis (D).  10. The system according to any one of paragraphs. 5-8, characterized in that it contains inlet nozzles (11) located in several places of the main channel (4) along the axis (D) and / or at some distance from it.  11. The system according to claim 10, characterized in that the inlet nozzles comprise at least one central nozzle (11 ') located on or near the axis (D) of the main channel and / or peripheral nozzles (11' ') located near the wall (4c) of the main channel, and / or median nozzles located between the axis of the main channel and its wall.  12. The system according to claim 11, characterized in that the peripheral nozzles (11 ") and / or middle nozzles are evenly distributed around the axis.  13. The system according to any one of paragraphs. 9-12, characterized in that the various inlet nozzles (11) are so located relative to each other that they essentially do not impede the passage of exhaust air.  14. The system according to any one of paragraphs. 9-13, characterized in that the various inlet nozzles are installed in rows and columns and rest on a perforated plate located in the main channel (4) and fixed in it.  15. The system according to any one of paragraphs. 5-14, characterized in that it contains means for selectively controlling the operation of various nozzles.  16. The system according to any one of paragraphs. 5-15, characterized in that at the exit of the inlet nozzles (11) is located at least one wall in the form of a venturi (13).  17. The system according to p. 16, characterized in that it contains a wall in the form of a venturi adjacent to the wall of the main channel (4), or / and a wall in the form of a venturi for at least one inlet nozzle of the same type, then there is a central, peripheral or median.  18. The system according to any one of paragraphs. 3-17, characterized in that the first device (7) for introducing additional air further comprises means (19) for creating a suction of additional air located at the second end (8b) of the additional channel (8).  19. A system according to claim 18, characterized in that the means (19) for creating a suction of additional air are made in the form of drive means, for example, in the form of a fan or similar device.  20. The system according to any one of paragraphs. 3-19, characterized in that the first device (7) for introducing additional air further comprises means (2b) for filtering and / or processing additional air.  21. The system according to any one of paragraphs. 3-20, characterized in that the first device (7) for introducing additional air also contains means (21) for heating or cooling the additional air.  22. The system according to p. 1 or 2, characterized in that the first device for introducing additional air to facilitate traction includes: an additional channel (23), which is part of the main channel (4), and a part (24), covered by the main channel (4 ) located in front of the extreme part (23a) of the additional channel (23) coaxially with it and made in the form of a sleeve forming an internal passage (24 ') for additional air and containing hollow grooves (28) passing along its outer surface (27) from end free inner edge (27a) to the peripheral zone (27c) and together with an additional channel (23), limiting channels for introducing additional air, while the peripheral zone (27c) together with the additional channel (23) limits the space for collecting additional air.  23. The system according to p. 22, characterized in that the grooves (28) are made axial or spiral.  24. The system according to p. 22 or 23, characterized in that the grooves (28) are located evenly on the outer surface (27) of the sleeve around its axis (L).  25. The system according to p. 24, characterized in that the number of grooves (28) is sufficient for their placement essentially close to each other.  26. The system according to any one of paragraphs. 22-25, characterized in that the specified part (24) contains the first part (24a) in the form of a crown, limiting grooves (28) and including a peripheral zone (27c), and a second part (24b) forming a support, the first part being installed on the second part.  27. The system according to any one of paragraphs. 22-26, characterized in that the specified part (24) is made integral.  28. The system according to any one of paragraphs. 22-27, characterized in that the inner and / or outer section of the specified part is round.  29. The system according to any one of paragraphs. 22-27, characterized in that the internal and / or external section of the specified part is polygonal.  30. The system according to any one of paragraphs. 22-29, characterized in that the internal shape of the specified part (24) at least at the end of the free inner edge (27A) is generally cylindrical.  31. The system according to p. 30, characterized in that the inner surface (25) of the first part (24a) has a substantially cylindrical shape, and the inner surface (30) of the second part (24b) has a substantially truncated cone shape, the large base of which is removed from the free edge (27a).  32. The system according to any one of paragraphs. 22-31, characterized in that the outside of the specified part (24) at least at the end of the free inner edge (27A) is made in the form of a truncated cone, the small base of which is located at the free edge so that the end parts of the grooves (28) slightly inclined relative to the longitudinal axis (L) of the part (24).  33. The system according to p. 32, characterized in that the outer surface (27) of the first part (24a) has a substantially truncated cone shape, and the outer surface (31) of the second part (24b) has a substantially cylindrical shape.  34. The system according to any one of paragraphs. 26-33, characterized in that on its outer surface it has a radial ledge (32), forming a boundary between the first (24a) and second (24b) parts.  35. The system according to any one of paragraphs. 22-34, characterized in that the additional channel (23) contains a first section (33) located opposite the outer surface (27) of the specified part containing the grooves (28), and close to this surface with the formation of channels for introducing additional air, and the second section (35), located opposite the peripheral zone (27c) and spaced from it with the formation between the corresponding outer surface (27) of the part and the second section (35) of the annular space (36), forming a collection chamber for additional air, and in the second section vyp ying at least one opening for introducing air into said chamber derived.  36. The system according to p. 35, characterized in that it contains means (37) for supplying air in communication with the collection chamber (36) through the specified hole.  37. The system according to p. 35 or 36, characterized in that the first section (33) of the additional channel (23) is made in the form of a truncated cone, the small base of which is located essentially opposite the free edge (27a) of the part (24), and the large base is located essentially opposite the boundary between the grooves (28) and the peripheral zone (27c).  38. The system according to p. 37, characterized in that the second section (35) of the additional channel has a substantially cylindrical shape, and a radial collar (33a) located outside forms the junction of the first (33) and second (35) sections.  39. The system according to any one of paragraphs. 35-38, characterized in that above the first section (33) of the additional channel (8) is a free section (34) of the additional channel.  40. The system according to p. 39, characterized in that the free section (34) is made in one piece with an additional channel (23).  41. A system according to claim 39 or 40, characterized in that the free section (34) is made in the form of a truncated cone, a large section of which is located on the side opposite to the specified part (24), with the formation of a venturi.  42. The system according to any one of paragraphs. 26-41, characterized in that the second part (24a) of the specified part (24) is inserted into the main channel (4) behind the exit from the second section (38), which is part of the main channel (4).  43. The system according to any one of paragraphs. 22-42, characterized in that it contains an intermediate part (39), covering the first device (7) for introducing additional air at least opposite the grooves (28).  44. Installation for natural ventilation of at least one room (2) of the building (3), characterized in that it contains: a system (1) for supplying air to the specified room (2) according to any one of paragraphs. 1-43, and a system (40) for removing air from said room (2).  45. Installation according to claim 44, characterized in that the air removal system (40) comprises: a main riser (41) that extends substantially vertically and whose output end (41a) is brought out to the removal zone (42), and the input end ( 41b) is closed, and at least one outlet pipe (43) is installed in the hole made in the main riser (41) between its inlet end (41b) and the outlet end (41a), and led into the corresponding room (2).  46. Installation according to claim 45, characterized in that the air removal system (40) further comprises a second device (44) for introducing additional air, essentially similar to the first device (7) for introducing an air supply system and installed at the output end (41a ) of the main riser (41).  47. Installation according to claim 45 or 46, characterized in that the air removal system (40) further comprises a static or stato-mechanical exhaust device (45) located at some distance from the output end (41a) of the main riser (41).  48. Installation according to claim 47, characterized in that the exhaust device (45) comprises a lower part (46) and an upper part (47) spaced apart and rigidly connected to each other along the axis (L) of the main riser (41) while the lower part (46) contains a passage (51) for passing the exhaust air, communicating with the main riser (41) and brought into the space (49) located between the lower (46) and upper (47) parts of the exhaust device.  49. Installation according to claim 48, characterized in that the space (49) between the lower (46) and upper (47) parts in a longitudinal section is generally the shape of a venturi.  50. Installation according to claim 48 or 49, characterized in that the exhaust device (45) has a generally shaped surface of revolution, the axis of which (48) is a continuation of the axis of the main riser (41) or slightly inclined with respect to it.  51. Installation according to any one of paragraphs. 48-50, characterized in that the lower part (46) of the exhaust device (45) contains at least one upper wall (52) in the form of a truncated cone, the small base of which faces the upper part (47), and the large base to the main riser (41).  52. Installation according to claim 51, characterized in that the lower part (46) of the exhaust device (45) also contains the lower wall (53) as a whole in the form of a truncated cone, the small base of which faces the main riser (41), and the large base - to the upper part (47).  53. Installation according to any one of paragraphs. 48-52, characterized in that the upper part (47) of the exhaust device (45) contains at least one lower wall (56) as a whole in the form of a simple or truncated cone, while the top (58) of a simple cone or a small base of a truncated cone facing the lower part (46), and the large base is located opposite the main riser (41).  54. Installation according to p. 53, characterized in that the upper part (47) of the exhaust device (45) also contains the upper wall (57) in the form of a cone, or a truncated cone, or a hemisphere, the large base of which is facing the lower part ( 46).  55. Installation according to any one of paragraphs. 47-54, characterized in that the exhaust device (45) also contains a built-in turbine, so that the exhaust device is stato-mechanical.  56. Installation according to any one of paragraphs. 44-55, characterized in that the first air source (5) of the air supply system (1) is separated from the removal zone (42) into which the main riser (41) is discharged.  57. Installation according to any one of paragraphs. 44-55, characterized in that the first air source (5) of the air supply system (1) is located in the removal zone (42) into which the main riser (41) is discharged.  58. Installation according to claim 57, characterized in that it further comprises a second riser (59), covering the main riser (41) and brought out on the one hand into the removal zone (42), and on the other hand into the supply pipe (60) connected to the main channel (4) of the air supply system (1), and the air (61) separating the main riser (41) from the second riser (59) receives air from the removal zone (42), which is then sucked into the supply pipe (60) and into the main channel (4) of the air supply system (1).  59. Installation according to p. 58, characterized in that the second riser (59) contains at least one hole (62), allowing passage of at least one outlet pipe (43) installed in the hole made in the main riser (41) .

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